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Mortality and hospitalizations due to cardiovascular and respiratory diseases associated with air pollution in Iran: A systematic review and meta-analysis
Accepted Manuscript Mortality and hospitalizations due to cardiovascular and respiratory diseases associated with air pollution in Iran: A systematic review and meta-analysis Behrooz Karimi, Behnosh shokrinezhad, Sadegh Samadi PII:
S1352-2310(18)30761-1
DOI:
https://doi.org/10.1016/j.atmosenv.2018.10.063
Reference:
AEA 16360
To appear in:
Atmospheric Environment
Received Date: 1 May 2018 Revised Date:
26 September 2018
Accepted Date: 29 October 2018
Please cite this article as: Karimi, B., shokrinezhad, B., Samadi, S., Mortality and hospitalizations due to cardiovascular and respiratory diseases associated with air pollution in Iran: A systematic review and meta-analysis, Atmospheric Environment (2018), doi: https://doi.org/10.1016/j.atmosenv.2018.10.063. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
ACCEPTED MANUSCRIPT Mortality and hospitalizations due to cardiovascular and respiratory diseases associated
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with air pollution in Iran: a systematic review and meta-analysis
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Behrooz Karimia,*, Behnosh shokrinezhada, Sadegh Samadib a
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6 Department of Environmental Health Engineering, Health Faculty, Arak University of Medical Sciences, Arak, b
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Iran; Department of Occupational Health, Health Faculty, Arak University of Medical Sciences, Arak, Iran;
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*Corresponding author; Behrooz Karimi; Department of Environmental Health Engineering, Health Faculty, Arak University of Medical Sciences, Arak, Iran Email: [email protected] Tel & Fax: +98 (0)863368443
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Air pollution is a major environmental health problem around the world. The purpose of this
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study was to investigate the relationship between exposure to air pollution with mortality and
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hospitalizations by conducting a systematic review and meta-analysis.
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Several databases were searched for studies exploring the relationship between air pollution
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and the all-cause, cardiovascular and respiratory mortality, as well as hospitalizations. The
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ABSTRACT
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each study included. Random-effects model was applied to estimate the relative risks of all-
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cause mortality and mortality/hospitalization due to cardiovascular and respiratory diseases.
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We found a 0.6% (95% CI 0.5%-0.7%) increase in all-cause, 0.5% (95% CI 0.4%-0.6%)
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risk of bias assessed by the Office of Health Assessment and Translation (OHAT) Method for
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per 10 µg/m3 increase of pooled all air pollutants. Moreover, we observed a 0.7% (95% CI
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0.6%-0.9%) increase in hospitalization due to cardiovascular and respiratory diseases per 10
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µg/m3 increase of pooled air pollutants. The highest all-cause mortality was associated with
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exposure to particulates with aerodynamic diameters less than 2.5 µm (PM2.5) (681 deaths or
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1.5%, 95% CI 1.3%-1.7%), followed by PM10 (253 deaths or 0.7%, 95% CI 0.6%-0.8%).
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The current study illustrated that all investigated air pollutants were associated with elevated
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mortality and hospitalization, but the effects of PM2.5 and PM10 were stronger. Thus,
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increase in cardiovascular, and 0.8% (95% CI 0.6%-0.9%) increase in respiratory mortality
authorities need to pay more attention to establishing the new regulations to apply control
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measures.
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Keywords: Mortality, Hospitalizations, Air pollution, Meta-analysis
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Systematic review registration: PROSPERO: CRD42018088770.
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Air pollution is a major environmental health problem around the world (Miri et al., 2016).
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Rapid urbanization and industrialization are well-known causes of increasing air pollution
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and subsequently associated with adverse health outcomes (Mannucci and Franchini, 2017;
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Miri et al., 2016). Air pollution has become the 4th highest-ranking risk factor for death in the
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world (Brauer, 2016). The world health organization (WHO) in 2016 reported that air
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pollution of fine particles associated with 4.2 million deaths annually (WHO, 2018). In 2018,
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this figure increased to be 7 million deaths (WHO, 2018). More than 90% of air pollution-
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1. Introduction
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Africa. Regarding Middle East, the highest concentrations of air pollution are in the Eastern
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Mediterranean Region and in South-East Asia, with annual mean concentrations often
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exceeding more than 5 times WHO limits (WHO, 2018).
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According to the global ranking, Iran was ranked as the seventh among the most 10 top
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polluted countries (Heger and Sarraf, 2018). Tehran is ranked as 12th among 26
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related deaths reported to be occur in low- and middle-income countries, mainly in Asia and
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Additionally, Tehran as a capital city was the third most top polluted city in the world after
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Jakarta (Indonesia) and Kolkata (India) (Sefiddashti et al., 2015). Air pollution is a major
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environmental risk factor for morbidity in Iran including diseases such as respiratory and
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megacities in terms of ambient PM10 concentrations (Heger and Sarraf, 2018).
cardiovascular diseases, lung cancer, Alzheimer’s and Parkinson’s diseases (Heger and
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Sarraf, 2018). The all-cause mortality attributed to air pollution in Tehran estimated to be
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5388 deaths (40% of all deaths) in 2008 (Joneidi jafari et al., 2010) and this figure was
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elevated to be 5894 in 2017 (Mohammadi-Zadeh et al., 2017).
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The concentrations of carbon monoxide (CO), sulfur dioxide (SO2) and nitric oxide (NO) in
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Tehran had downward trends during the years 2002-2017 (Arhami et al., 2017; Zarandi et al.,
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2015), while the concentrations of PM2.5, PM10, nitrogen dioxide (NO2) and ozone (O3) had
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respectively, about 3 and 4 times higher than the national standard limits in 2017
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(Khodarahmi et al., 2016). Similarly, the concentrations of CO, SO2, NO, NO2 and O3 were
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reported to be somewhat high as well (Ghozikali et al., 2016).
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The relationship between air pollution and mortality/hospitalizations in the countries has been
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well-established (Atkinson et al., 2015; Khaniabadi et al., 2018; Rückerl et al., 2011).
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Numerous cohort studies suggesting a relationship between long-term exposure to air
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pollution and mortality in the world, especially with rapid urbanization and industrialization
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rising trends (Jaafari et al., 2017). The mean concentrations of PM2.5 and PM10 were,
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2016; Fischer et al., 2015; Pope III et al., 2017). Traffic and combustion sources have been
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previously associated with short-term cardiovascular and respiratory diseases (Bravo et al.,
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2017; Kim et al., 2012; Samoli et al., 2016). Moreover, there is increasing evidence of the
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effects of PM with aerodynamic diameters less than 10 and 2.5 µm (PM10 and PM2.5) on
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cardiovascular disease and respiratory disease (Kloog et al., 2014; Lepeule et al., 2012; Lu et
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(Ancona et al., 2015; Beelen et al., 2014; Cesaroni et al., 2013; Chen et al., 2013; Chen et al.,
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associated with air pollution related to mortality and hospitalization in various Iranian cities.
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However, there is no complete and comprehensive analysis of these data, which together with
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their integration should generate the precious conclusion. Hence, we decided to do a
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al., 2015). Various studies have been carried out concerning the adverse health effects
systematic review and meta-analysis of these data. The objective of this review was to
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perform a systematic review and meta-analysis of the epidemiological studies to evaluate
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mortality and hospitalizations due to cardiovascular and respiratory diseases associated with
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air pollution in Iran.
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2. Methods
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PROSPERO and is available at https:// www. crd. york. ac. uk/ PROSPERO/ display_record
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.asp ? ID=CRD42018088770. A complete PRISMA (Preferred Reporting Items for
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Systematic Reviews and Meta-Analysis) checklist (Moher et al., 2015) is presented in the
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supplementary material (Table S1).
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The protocol information for present systematic review and meta-analysis were registered on
2.1. Study selection
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Two investigators (B.K and B.S) simultaneously searched the databases of PubMed,
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MagIran, IranMedex and Scientific Information Databank (SID). The databases were
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searched from January 1980 to January 2018 for studies investigating the all-cause mortality
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as well as mortality and hospitalization relevant to cardiovascular and respiratory diseases
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which linked with exposure to air pollution. The following search keywords were used “air
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pollution”, “air pollutant”, “particulate”, “particles”, “PM10”, “PM2.5”, “carbon monoxide”,
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EMBASE, Web of Science, Scopus, Ovid, Google Scholar; and Iranian databases including
“CO”, “nitrogen dioxide”, “NO2”, “nitric oxide”, “nitrogen oxide”, “nitrogen monoxide”,
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“NO”, “sulfur dioxide”, “sulphur dioxide”, “SO2”, “ozone” or “O3” linked with “mortality”,
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“cardiopulmonary
“hospital
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admission” or “human health”. The reference lists of eligible articles were explored to find
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“respiratory
mortality”,
“hospitalization”,
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mortality”,
the most relevant articles as well. Using PRISMA guidelines, article titles and abstracts were
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first judged independently by two authors to choose the appropriate studies. The final
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inclusion of studies was made on the basis of full article investigation. In cases of
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uncertainties and inconsistency, the differences were resolved by a third author (SS).
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Publications were judged to be included in this review study if following inclusion criteria
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applied: they reported a risk estimate for the relationship between exposure to air pollution
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and all-cause mortality as well as mortality/hospitalization due to cardiovascular and
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studies, and review studies were excluded.
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Information for each study was extracted by two authors independently, including the name
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of the first author, study design, year of study, sample size, concentrations of air pollutants,
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the main findings of mortality or hospitalization, latitude, province, city, and year of
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publication (Supplementary Table S1, Appendix A). The following extracted information for
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2.2. Data extraction
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pollutants, relative risk (RR) with 95% confidence interval (CI), numbers of all-cause
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mortality, as well as mortality/hospitalization due to cardiovascular and respiratory diseases.
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2.3. Risk of bias assessment
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the present review study was used: mean concentrations and standard deviations of air
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The risk of bias of each study was evaluated using the Office of Health Assessment and
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Sciences-National Toxicology program (NIEHS-NTP) and the Navigation Guide from the
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University of California, San Francisco (OHAT, 2015). The risks of bias were assessed for
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following items: selection bias, confounders, exposure assessment, outcome assessment,
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Translation (OHAT) method presented by the National Institutes of Environmental Health
incomplete outcome data, selective reporting, and conflict of interest (Table 2 and more
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analytically in Table S2 Appendix B and C). With regards to pre-specific criteria, the risk of
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bias per each item was given as “low”, “probably low”, “probably high”, “high”, or “not
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applicable”.
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2.4. Data analysis
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College Station, TX) and R software version 3.3.2 (R Core Team 2015). The heterogeneity of
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studies was assessed by both Q test (P<0.10 as significant) and the coefficient of
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inconsistency (I2). The value of I2 equals 25% indicating low heterogeneity and if it exceeds
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75% suggesting high heterogeneity. Random-effects models and fixed-effect models were
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applied to calculate the effect size of studies based on Mantel-Haenszel and DerSimonian
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methods, respectively (DerSimonian and Laird, 1986). The pooled effect estimates of the
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concentration of all air pollutants and the RR with 95% CI for mortality/hospitalization were
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Statistical analyses were performed with STATA software version 12 (STATA Corporation,
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were computed according to the following formula.
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calculated using the random-effects models. The percent changes in mortality/hospitalization
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The publication bias was examined by constructing funnel plots of the log risk ratio versus
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the standard error (SE). The source of heterogeneity was investigated by the application of
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meta-regression analysis for geographical latitude, year of study and sample size.
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Percent change (%) = (ln (RR-1)) × 100%
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and the causes of mortality and hospitalization. Begg’s and Egger’s tests were used for the
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regression asymmetry test (P<0.10 as significant) and adjusted for publication bias following
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the “Trim and Fill” method if needed. Sensitivity analysis was performed to determine the
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Additionally, the subgroup analyses were performed by study design, type of air pollutants,
effect of removing each study.
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3. Results
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3.1. Included studies
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With a preliminary search of national and international databases, 1704 peer-reviewed studies
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were identified. Of them, 197 articles were excluded because of the overlap between
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databases. By reviewing the remaining articles, 1424 articles were removed since they were
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read and after a qualitative assessment, 45 articles were also excluded. Finally, 38 articles
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were fulfilled the quality assessment criteria and they were included in this meta-analysis
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(Fig. 1). Of which, 36 studies were cross-sectional and 2 time-series. Twenty four articles
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simultaneously examined both mortality and hospitalization, 2 studies only explored all-cause
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mortality, 3 studies investigated mortality related to both cardiovascular and respiratory
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diseases, and 4 studies explored hospitalization related to both cardiovascular and respiratory
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diseases (Table 1). Table 2 shows the risk of bias for each selected study. Further details of
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unrelated to the aim of this study. The full texts of the remaining 83 articles were completely
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Concerning the exposure assessment, the risk of bias was ‘low’ in the most of cases,
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‘probably low’ risk or ‘probably high’ risk in some cases, and only two studies had ‘high’
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risk.
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Table 1. Studies included in the meta-analysis
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individual studies are given in supplementary material (Table S2, Appendix B, and C).
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Table 2. Risk of bias rating for each study.
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Fig.1. PRISMA flowchart for literature selection and study identification (Moher et al., 2015)
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Table 3 provides the pooled mean concentrations of O3, PM2.5, PM10, NO2, NOx, SO2 and
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3.2. Concentrations of air pollutants
CO. As shown in Table 3, the pooled mean concentrations of CO and PM10 were the highest
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exposure (2620 mg/m3 and 112.3 µg/m³), followed by NOx (95.9 µg/m³). The forest plots of
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pooled concentrations of O3, PM2.5, PM10, NO2, NOx, SO2, and CO are given in
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supplementary material (Figs. S1-4, Appendix C). Fig. 2 shows the mean concentration of
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PM10 and the mean number of mortalities caused by PM10 derived from studies. The highest
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concentrations of PM10 were observed in cities located in the western part of Iran.
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locations.
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Table 3. Pooled mean concentrations of O3, PM2.5, PM10, NO2, NOx, SO2 and CO derived from studies.
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3.3. All-cause mortality
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in Table 3. The highest all-cause mortality was associated with exposure to PM2.5. The forest
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plots of the association between all-cause mortality and exposure to O3, PM2.5, PM10, NO2,
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NOx, SO2, CO are presented in supplementary material (Figs. S5-10, Appendix D). Using
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The association between the pooled amounts of all-cause mortality and air pollutants is given
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46.4 µg/m³ which was responsible for the high mortality rate (680 deaths), and PM10 with a
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pooled mean concentration of 112.3 µg/m³ attributed to the second highest mortality rate (253
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deaths) (Table 4). An increasing of concentrations of PM10 and PM2.5 were associated with an
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elevating of all-cause mortality after considering the quartile of mortality rate (Fig. 3 (A) and
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(B)). The pooled percent changes for all-cause mortality rate in relation to exposure to all air
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pollutants were 0.6% (95% CI 0.5%-0.7%). For all-cause mortality, the highest percent
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random-effects model, the results showed that the pooled mean concentration of PM2.5 was
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changes in all-cause mortality rates with regard to the type of air pollutants are illustrated in
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change (1.5%, 95% CI 1.3%-1.7%) was related to PM2.5 exposure. The pooled percent
Fig. 4 (A).
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Table 4. The pooled numbers of all-cause mortality related to O3, PM2.5, PM10, NO2, NOx, SO2 and CO.
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Fig. 3. The association between (A) PM10 and (B) PM2.5 and number of all-cause mortality.
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3.4. Cardiovascular mortality
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increase in all air pollutants. The same increase (0.5%, 95% CI 0.4%-0.6%) in cardiovascular
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mortality per 10 µg/m3 increase in PM2.5 was observed as well. The highest percent change
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increase in cardiovascular mortality (35.5%, 95% CI 8.5%-58.5%) was related to CO
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exposure. The second highest percent change in cardiovascular mortality (0.8%, 95% CI
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0.6%-1.0%) was related to SO2 exposure. The pooled percent changes in cardiovascular
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mortality rates with regard to the type of air pollutants are illustrated in Fig. 4 (B). The
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association between the pooled numbers of cardiovascular mortality and air pollutants is
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We obtained a 0.50% (95% CI 0.4%-0.6%) increase in cardiovascular mortality per 10 µg/m3
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to O3, PM2.5, PM10, NO2, NOx, SO2, and CO are presented in supplementary material (Fig.
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S11, Appendix D).
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given in Table 3. The forest plots of cardiovascular mortality rates associated with exposure
3.5. Respiratory mortality
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pollutants are illustrated in Fig. 4(C). A 10 µg/m3 increase in all air pollutants corresponded
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The pooled percent changes in respiratory mortality rates with regard to the type of air
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respiratory mortality (2.4%, 95% CI -5.8%-10.7%) was related to CO exposure, the second
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highest percent change in respiratory mortality (1%, 95% CI, 0.6%-1.3%) was related to
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PM10 exposure. The association between the pooled numbers of respiratory mortality and air
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to a 0.8% (95% CI 0.6%-0.9%) in respiratory mortality. The highest percent change in
pollutants is given in Table 3(C). Among all air pollutants, the highest respiratory mortality
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rate was associated with exposure to PM2.5 (490 deaths). The forest plots of all-cause
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mortality rates associated with exposure to O3, PM2.5, PM10, NO2, NOx, SO2, and CO are
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presented in supplementary material (Fig. S12, Appendix D).
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3.6. Hospitalization due to cardiovascular and respiratory diseases
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and respiratory diseases in relation to exposure to all air pollutants were 0.7% (95% CI 0.6%-
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0.9%). The highest pooled percent change for hospitalization was related to CO exposure
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(17.3%, 95% CI 3.0%-31.5%), and the second highest percent change was related to SO2
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exposure (1.3%, 95% CI 0.1%-2.5%). The association between the pooled numbers of
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hospitalization and air pollutants is given in Table 3 (D). Among all air pollutants, the highest
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hospitalization was associated with exposure to PM2.5 (1558 cases), followed by PM10 (563
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cases). The forest plots of hospitalization associated with exposure to O3, PM2.5, PM10, NO2,
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NOx, SO2, and CO are presented in supplementary material (Fig. S13, Appendix D).
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As shown in Fig. 4(D), the pooled percent changes for hospitalization due to cardiovascular
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Fig. 4. Pooled percent changes in (A) all-cause, (B) cardiovascular and (C) respiratory mortality, and (D)
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hospitalization in relation to pooled concentrations of CO, NO2, O3, PM10, PM2.5, and SO2 with 95% CI.
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3.8. Additional analyses
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significant source of heterogeneity (p<0.05), while the year of study and sample size were
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not. Funnel plot was slightly asymmetric and the result of Egger's test was significant
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Using a meta-regression model, the findings showed that only geographical latitude was a
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method showed that 57 studies required to obtain a full symmetry in Funnel plot (Q=421 and
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(p<0.001) (supplementary material, Figs. S14-16, Appendix D). Using the trim and fill
p<0.001) (supplementary material, Fig. S17, Appendix D). The sensitivity analysis test
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showed that there was no significant change in the results (supplementary material, Fig. S18,
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Appendix E).
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4. Discussion
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The results of this study showed a significant relationship between mortality and
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hospitalization with exposure to air pollutants of O3, PM2.5, PM10, NO2, NOx, SO2, and CO.
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60.1, 46.4, 112.3, 58.0, 95.9 and 34.8 µg/m³. Among these air pollutants, the pooled mean
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concentration of PM10 (112.3 µg/m3) was the highest exposure and this concentration was
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2.26 times greater than the concentration (50 µg/m3) suggested by the WHO guideline (Miri
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et al., 2016). The pooled mean concentration of PM2.5 (46.4 µg/m3) was 1.85 times greater
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than the concentration (25 µg/m³) proposed by WHO guideline (Miri et al., 2016). Beelen et
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al. in a study found that a concentration of about 20 µg/m³ of PM2.5, slightly lower than the
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concentration (25 µg/m³) suggested by WHO guideline, associated with an increased risk of
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The pooled mean concentrations for O3, PM2.5, PM10, NO2, NOx, and SO2 were, respectively;
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considerably high concentrations of PM2.5 and PM10 (Goudarzi et al., 2017; Goudarzi et al.,
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2015b; Shahsavani et al., 2012). Shahsavani et al. in a study found substantially higher
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concentrations of PM10 (319.6 ± 407 µg/m3) and PM2.5 (69.5 ± 83.2 µg/m3) (Shahsavani et
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al., 2012). Similarly, Goudarzi et al. in two studies measured a remarkably high concentration
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of PM10 which was probably related to dust storms (in respectively 261 and 360 µg/m3)
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mortality (Beelen et al., 2014). Three studies we included in this meta-analysis, they reported
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concentrations of PM2.5 and PM10 reported by these 3 studies could be contributed to high
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pooled concentrations of PM2.5 and PM10 observed in this meta-analysis. In agreement with
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remarkably high pooled concentrations of PM2.5 and PM10 in this review, a study carried out
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(Goudarzi et al., 2017; Goudarzi et al., 2015b). Thus, findings of considerably high
by Draxler et al. in countries located in the west and south of Iran, the concentrations of
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PM10 reported to be very high (3000 µg/m3) (Draxler et al., 2001). However, this
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concentration was almost 27 times higher than the pooled mean concentration of PM10
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obtained from this study. Meng and Lu found that the mean concentration of PM2.5 was 217
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µg/m3 (Meng and Lu, 2007) which were 4 times higher than the pooled mean concentration
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of PM2.5 in the present study. These findings proposed that probably dust storms in this meta-
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analysis could be an important source of high concentrations of PM10. The other possible
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close to cities.
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We observed an association between the increasing concentration of PM2.5 and the elevating
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risks of the all-cause, cardiovascular and respiratory mortality. In parallel to our findings,
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Beelen et al. reported that the most cases of mortality due to particulate matter were related to
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PM2.5, while coarse particles had less effect (Beelen et al., 2014). The same results were also
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reported in nurses’ health study (Puett et al., 2009). The association between the percent
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changes in all-cause, cardiovascular and respiratory mortality and PM10 and PM2.5 for 10-
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µg/m3 increase in this study has been compared with other studies in Table 5.
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sources could be particulate matters released from cars as well as industries which located
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Table 5. The percent change of all-cause, cardiovascular and respiratory mortality (95% CI) for a 10-µg/m3
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increase in the average concentration of PM10 and PM2.5 in this study compared with other studies
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We found that the pooled RR of all-cause mortality based on 10 µg/m³ increase of PM2.5 was
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the RRs of mortality from long-term exposure to PM2.5 were 1.04, 1.06, and 1.13,
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respectively; which were slightly higher than our results (Ballester et al., 2008; Beelen et al.,
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1.015. Three studies conducted by Ballester et al., Pope et al. and Beelen et al. showed that
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Society Study on Los Angeles population reported being much higher (Jerrett et al., 2005).
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2014; Pope III et al., 2002). The RR of mortality (1.17) related to PM2.5 exposure in cancer
In the present study, the health effects reported by studies differed. The discrepancy in
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relation to the estimating of the health effects between studies might be explained by different
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definitions used for health effects. Other factors such as population size, sources of air
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pollution, the intensity of exposure, and the components of PMs might be responsible for
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observed health effects. The underlying mechanisms of health effects associated with PMs
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are poorly understood. Nonetheless, PMs are well-known causing biochemical stresses such
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as systemic inflammation and oxidative stress (Møller et al., 2014). Chronic inflammation
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known as indicators of the biological aging of cells (Karimi et al., 2017). To confirm this,
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McCracken et al. in a study among the elderly population found that the prolonged exposure
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to PM in high traffic areas associated with a shortened length of telomere (McCracken et al.,
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2010).
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and oxidative stress are associated with shortened telomeres, and subsequently, they are
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1.001–1.004), which was lower than those RR values reported by Beelen et al. (1.01, 95% CI
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0.99–1.03) and Mills et al. (1.007, 95% CI 1.004–1.010) (Beelen et al., 2014; Mills et al.,
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In the present study, the RR value for all-cause mortality due to NO2 was 1.003 (95% CI
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respiratory diseases such as asthma and subsequently the number of hospitalizations due to
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respiratory diseases increased (Mohammadi et al., 2016). Since most of the Iranian people
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often use their own cars, the high exposure to NO2 in the present study could be explained by
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the high number of cars used and also the intense traffic jam.
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The trend of O3 concentration in Iran has been steadily increased over the last two decades,
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2015) A study reported that exposures to NO2 were associated with the prevalence increase of
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elevated concentration of 10 µg/m3 of O3 resulted in an increase of 0.4% in all-cause
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mortality. This finding was roughly close to those results reported by four studies: a meta-
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analysis study conducted by WHO (0.3%), a systematic review of Chinese studies (0.48%),
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with higher concentrations in the warm seasons (Zarandi et al., 2015). We revealed that the
the Chinese PAPA study (0.31%), and a Canadian cohort study with a follow-up of 16 years
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(0.34%)(Anderson et al., 2004; Crouse et al., 2015; Shang et al., 2013; Wong et al., 2008). In
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contrast, Carey et al. and Ghorbani et al. observed a negative relationship between the annual
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mean concentration of O3 and the mortality rate (both RR=0.98) (Carey et al., 2013;
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Ghorbani et al., 2017).
349
Among the air pollutants, an increase of 10 mg/m3 in CO concentration was significantly
350
associated with an elevated RR of hospitalization (1.173, 95% CI 1.030–1.315). Zheng et al.
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findings found that the RR of hospitalization related to CO exposure was 1.045 (95% CI
353
1.029-1.061) which was somewhat lower than our RR value, while a considerably higher RR
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(1.490, 95% CI 1.250-1.770) was found by Shahi et al. (Shahi et al., 2014). The mechanism
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of health effects related to CO is poorly understood. Nonetheless, CO quickly bonds with
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hemoglobin and interferes with oxygen release in tissues. Then, cardiovascular dysfunction
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includes myocardial infarction, arrhythmia and angina could occur (Lee et al., 2015).
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The estimates derived from this study could be applied to health risk assessments of air
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(Zheng et al., 2015) in a systematic review and meta-analysis study in accordance of our
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effectively synthesize existing data of all types and design data collection efforts in a variety
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of research contexts. However, evidence of mortality and hospitalizations, especially for
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chronic obstructive pulmonary disease (COPD) and myocardial infarction, is still insufficient
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for meta-analysis.
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5. Conclusions
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pollutants in Iran and a meta-analysis is a versatile tool that can help researchers more
365 366 367
associated with air pollution in Iran. All investigated air pollutants were associated with
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increased risk of mortality and hospitalization due to cardiovascular and respiratory diseases,
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This is the first systematic review and meta-analysis of mortality and hospitalization
but the effects of PM2.5 and PM10 were stronger. So identifying the concentrations and
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sources of air pollutants will help to establish the new regulations for control measures. This
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subsequently leads to the diminishing of mortality and hospitalization. Moreover, further
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cohort-based studies in this field are needed to be conducted to better investigate the effects
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of air pollution on health effects.
374 375
Acknowledgments: This study was supported by Arak University of Medical Sciences, Iran. The authors will
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like to thank Dr. Masoud Behzadfar for providing us the additional analyses.
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ACCEPTED MANUSCRIPT 378 Supplementary data
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Supplementary data to this article can be found in Tables S1-2 and Figs S1-18.
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ACCEPTED MANUSCRIPT Table 1. Studies included in the meta-analysis. Type of study Cross- sectional
Pollutants O3
Kerman, 2006 - 2010
Time series
3
(Mokhtari et al., 2015)
Yazd, 2013-2014
ecological
PM10, CO, NO, NO2, NOx, O3, SO2 PM10, PM2.5, SO2
4
(Daryanoosh et al., 2017)
Ahvaz, Khorramabad, Ilam
Cross- sectional
PM10
5
(Goudarzi et al., 2015b)
Ahvaz, during 2009
Cross- sectional
PM10
6
(Kermani et al., 2015)
Cross-sectional
O3
7
(Kermani et al., 2016b)
Mashhad, Tabriz, Shiraz, Isfahan and Arak, 2011. 8 industrial cities of Iran, 2011
Cross-sectional
PM2.5, CO
8
(Kermani and Aghaei, 2016)
Tehran, 2012
Cross-sectional
PM10, PM2.5, SO2
9
(Ghorbani et al., 2017)
Mashhad, 2012
Cross-sectional
10
(Kermani et al., 2016a)
Tehran, 2014
CO, SO2, NOx, NO2, NO, O3 NO2, O3
11 12
(Ghozikali et al., 2016) (Miri et al., 2016)
Tabriz, 2011–2012 Mashhad, 2012
13 14 15 16 17 18 19
(Goudarzi et al., 2017) (Shahsavani et al., 2012) (Marzouni et al., 2016) (Omidi et al., 2016) (Goudarzi et al., 2015a) (Khaniabadi et al., 2017a) (Nikoonahad et al., 2017)
Kermanshah, 2014 - 2015 Ahvaz, 2010 Kermanshah, 2011- 2012 Kermanshah Ahvaz Kermanshah, 2014– 2015 Ilam, 2014–2015
Cross- section Cross- section Cross- section Cross- section Cross-sectional Cross-sectional Cross-sectional
20 21 22 23 24 25 26 27
(Mohammadi et al., 2016) (Naddafi et al., 2012) (Gholampour et al., 2014) (Zallaghi et al., 2014) (Mohammadi et al., 2015) (Khaniabadi et al., 2017b) (Bahrami Asl et al., 2015) (Dadbakhsh et al., 2015)
Shiraz, 2012 Tehran, 2012 Tabriz, 2012 - 2013 Ahvaz 2010 - 2013 Shiraz, 2013 Kermanshah, 2014 - 2015 five metropolises, 2011-2012 Shiraz, 2006-2012
Cross-sectional Cross-sectional Cross-sectional Cross-sectional Cross-sectional Cross-sectional Cross-sectional Cross-sectional
28 29 30 31 32 33 34 35 36 37
(Nourmoradi et al., 2015) (Hosseini et al., 2014) (Geravandi et al., 2016) (Goudarzi et al., 2012) (Zallaghi, 2014) (Geravandi et al., 2015) (Zallaghi et al., 2015) (Nourmoradi et al., 2016) (Gharehchahi et al., 2013) (Shahi et al., 2014)
Khorramabad, 2014 Sanandaj, Kurdistan, 2013 Ahvaz 2011 Ahvaz 2009 Kermanshah 2011 Ahwaz, Bushehr, Kermanshah, 2011 Tabriz, 2015 Khorramabad Shiraz, 2008-2010 Tehran, 2012
Cross-sectional Cross-sectional Cross-sectional Cross-sectional Cross-sectional Cross-sectional Cross-sectional Cross-sectional Cross-sectional Time series
38
(Khamutian et al., 2014)
Kermanshah, 2010-2011
Cross-sectional
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Location/Period Tabriz, Iran: 2014
2
Study (Ghanbari Ghozikali et al., 2014) (Khanjani et al., 2012)
Cross-sectional
Cross-sectional Cross- section
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O3, SO2 NO2 PM10, PM2.5, O3, NO2, SO2 PM10 PM10, PM2.5 PM10 NO2, O3 O3 PM10, NO2, O3 PM10 PM10, SO2, NO2, O3 O3, NO2, PM10, SO2 PM2.5, PM10 PM10 PM10 O3 NO2 O3, SO2, CO, PM10, NO, NO2, NOx PM10 PM10 O3 NO2 PM10 PM10, NO2 NO2 PM10 PM10, SO2, NO2 O3, NO2, SO2, PM10, PM2.5, CO NO, PM10, CO, O3, SO2
ACCEPTED MANUSCRIPT Table 2. Risk of bias rating for each study
23 24 25
Zallaghi et al. 2010
26 27 28
Bahrami et al. 2011
29 30
Hosseini et al. 2014
31
Goudarzi et al. 2011
32 33 34 35
Zallaghi et al. 2009
36
Gharehchahi et al. 2008
37
Shahi et al. 2012
Omidi et al. 2014 Goudarzi et al. 2012 Omidi et al. 2014 Nikoonahad et al. 2014 Mohammadi et al. 2012 Naddafi et al. 2012
Selection bias
Incomplete outcome data
Selective outcome reporting
Conflict of interest
Other
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Dadbakhsh et al. 2009 Nourmoradi et al. 2006
Confounding
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Ghanbari et al. 2014 Khanjani et al. 2014 Mokhtari et al. 2013 Daryanoosh et al. 2014 Goudarzi et al. 2009 Kermani et al. 2011 Kermani et al. 2011 Kermani et al. 2013 Ghorbaniet al. 2011 Kermani et al. 2014 Ghanbari et al. 2011 Miri et al. 2015 Goudarzi et al. 2014 Shahsavani et al. 2010 Bagherian et al. 2011
Outcome assessment
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Exposure assessment
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Geravandi et al. 2013
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Nourmoradi et al. 2015
38 Khamutian et al. 2010 Risk of bias rating
Low
Probably Low
Probably high
High
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Table 3. Pooled mean concentrations of O3, PM2.5, PM10, NO2, NOx, SO2 and CO derived from studies.
O3 PM2.5 PM10 NO2 NOx SO2 CO
mean
lower
upper
Standard
Heterogeneity
df
P
I-squared
Tau-squared
60.1 46.4 112.3 57.9 95.8 34.8
45.7 31.3 73.0 46.4 24.1 19.7
74.4 61.5 151.6 69.5 167.6 49.8
2620.3
1569.1
3672.6
159 35 150 100 196 10000
66.5 2.3 89.9 28.1 0.41 28.8 5.7
19 14 26 20 2 12 5
0.00 1 0.00 0.10 0.80 0.004 0.34
71.40% 0.00% 71.10% 11.90% 0.00% 58.30% 89.70%
479.9 0 5500 0.16 0 296.8 201.8
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Pollutants
Heterogeneity
df
P
I-squared
Tau-squared
273.5 178.6 871.0 267.6 242.8 92.4 4.8 72.8
3898.1 3.6 834.3 15597.8 1930.2 650.9 56.6 34822.1
47 3 15 98 22 22 7 227
0 0.312 0 0 0 0 0 0
98.8% 15.9% 98.2% 99.4% 98.9% 96.6% 87.6% 99.3%
13000 768.1665 140000 3300 9500 898.475 3.6099 114.7866
297.3 187.1 140.7 4.8 281.4 335.5 28.2
779.7 1428.4 174.6 56.6 714.6 6970.9 12951.7
13 18 6 7 8 2 61
0 0 0 0 0 0 0
98.3% 98.7% 96.6% 87.6% 98.9% 100.0% 99.5%
2.40E+04 2.00E+03 2.20E+03 3.6099 1.30E+04 77.235 44.0957
259.3 53.6 50.5 430.5 812.0 86.4
492.7 830.5 129.7 3.8 0.0 2202.0
13 18 6 1 0 44
0 0 0 0.052 . 0
97.4% 97.8% 95.4% 73.5% .% 98.0%
6.80E+03 276.4695 320.9848 7.80E+03 0 570.446
381.9 645.6 244.7 768.9 2485.5 398.2
431.0 8851.2 401.4 40.8 0.0 10918.4
7 41 5 3 0 64
0 0 0 0 . 0
98.4% 99.5% 98.8% 92.6% .% 99.4%
2.70E+04 6.20E+04 1.90E+04 1.10E+05 0 1.70E+04
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upper
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Pollutants mean lower A) All-cause mortality O3 236.8 200.1 TSP 114.0 49.5 PM2.5 680.5 490.1 PM10 252.9 238.2 NO2 199.2 155.5 SO2 76.5 60.5 CO 3.0 1.3 Overall 70.1 67.5 B) Cardiovascular mortality O3 211.0 124.7 PM10 159.8 132.4 SO2 99.5 58.3 CO 3.0 1.3 NO2 204.0 126.6 PM2.5 167.0 10.0 Overall 25.3 22.3 C) Respiratory mortality O3 209.3 159.2 PM10 43.2 32.8 SO2 35.1 19.6 NO2 291.7 153.0 PM2.5 490.0 168.0 Overall 76.9 67.4 D) Hospitalization O3 246.5 111.0 PM10 563.4 481.2 NO2 128.6 12.5 SO2 418.6 68.3 PM2.5 1558.0 630.5 Overall 60.9 323.7
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Table 4. Pooled numbers of all-cause mortality related to O3, PM2.5, PM10, NO2, NOx, SO2 and CO.
ACCEPTED MANUSCRIPT Table 5. The percent change of all-cause, cardiovascular and respiratory mortality (95% CI) for a 10-µg/m3 increase in the average concentration of PM10 and PM2.5 in this study compared with other studies cardiovascular mortality 0.9%, 95% CI 0.3%–1.4% 0.43%, 95% CI 0.37%–0.5% 0.9%, 95% CI 0.5%–1.3% 0.58, 95% CI 0.22%–0.93% 0.44, 95% CI 0.19%–0.68% 0.7%, 95% CI 0.4%–1% – 0.44%, 95% CI 0.33%–0.54% 0.58, 95% CI 0.22%–0.93% 0.44, 95% CI 0.19%–0.68% 0.5%, 95% CI 0.1%–2.0%
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(Atkinson et al., 2012) (Shang et al., 2013) (Anderson et al., 2004) (Wong et al., 2008)(4 cities) (Wong et al., 2008) (3 Chinese cities) This study Study (Franklin et al., 2007) (Shang et al., 2013) (Wong et al., 2008)(4 cities) (Wong et al., 2008) (3 Chinese cities) This study
PM10 all-cause mortality 0.3%, 95% CI 0.1%–0.4% 0.32, 95% CI 0.28%–0.35% 0.6%, 95% CI 0.4%–0.8% 0.55, 95% CI 0.26%–0.85% 0.37, 95% CI 0.21%–0.54% 0.7%, 95% CI 0.6%–0.8% PM2.5 1.21%, 95% CI 0.29%– 2.14% 0.38%,95% CI 0.31%– 0.45% 0.55, 95% CI 0.26%–0.85% 1.37, 95% CI 0.21%–1.54% 1.5%, 95% CI 1.3%–1.7%
respiratory mortality 0.4%, 95% CI 0.1%–0.6% 0.32, 95% CI 0.23%–0.40% 1.3%, 95% CI 0.5%–2.0% 0.62, 95% CI 0.22%–1.02% 0.60, 95% CI 0.16%–1.04% 1.0%, 95% CI 0.6%–1.3%
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1.03% 95% CI 0.02%–2.04% 0.51% 95% CI 0.30%–0.73% 0.62, 95% CI 0.22%–1.02% 0.60, 95% CI 0.16%–1.04% 0.8%, 95% CI 0.4%–1%
Identification
ACCEPTED MANUSCRIPT Records identified through database searching (N =1675)
Additional records identified through other sources (N =29; from reference)
Records screened (N =1507)
Records excluded (N =1424)
Full-text articles excluded, with reasons: Not relevant studies to CVD or Respiratory and COPD, N = 30 Abstract only, N= 5 Small sample sizes, N= 8 Letter comments, correspondence, N = 2
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Eligibility
Full-text articles assessed for eligibility (N =83)
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Screening
Records after duplicates removed (N =197)
Included
Studies included in qualitative synthesis (N =38)
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Studies included in quantitative synthesis (metaanalysis) (N =38)
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Fig 1. PRISMA Flowchart for literature selection and Study identification (Moher et al., 2015)
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( ! Ardabil
East Azerbaijan
Golestan
( ! Gilan
! (
Kurdistan
Hamadan ( !
5
Kermanshah
PM10 (µg/m3) 20 - 60
( ! Markazi
! (
( ! Ilam
Lorestan
! (
! (
Tehran
( Isfahan!
Yazd
! (
( and Bakhtiari Chaharmahal!
Khosestan
! (
( Boyer-Ahmad ! Kohgiluyeh and
Mortality ( !
! (
40 - 70
71 - 360
! (
361 - 1109
! (
1110 - 2141
EP ( ! Bushehr
( ! South Khorasan
Kerman ( !
! (Fars
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131 - 269
! (
( ! Semnan
( ! Qom
61 - 100
101 - 130
Razavi Khorasan
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( ! Qazvin
( ! Mazandaran
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( ! North Khorasan
( !
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! (
( !
( !
Hormozgan ( !
Sistan and Baluchestan
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A
80
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PM2.5 (µg/m3)
200
100
Lower 230
Between 231-645
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All-cause mortality
Higher 642
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PM10 (µg/m3)
100
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300
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B
40
Lower 210
Between 211-770
All-cause mortality
Higher 770
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A
B 2
1
0
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0.5
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1.0
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% Change
% Change
1.5
-1
NO2
O3
SO2
PM10
CO
C
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5
0
Pooled
PM2.5
PM10
SO2
O3
NO2
NO
NOx
D 2.5 2.0
% Change
EP
10
% Change
PM2.5
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1.5 1.0 0.5
-5
0.0 Pooled
CO
NOx
NO2
NO
SO2
PM10
O3
Pooled
SO2
NO
PM2.5
PM10
O3
NO2
ACCEPTED MANUSCRIPT Highlights The relationship between exposure to air pollution with mortality and hospitalizations by conducting a systematic review and meta-analysis The risk of bias assessed by the Office of Health Assessment and Translation (OHAT) Method for each study included
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The percent change of all-cause, cardiovascular and respiratory mortality and hospitalization (95% CI) for a 10-µg/m3 increase in the PM10, PM2.5, O3 and CO (per each 10 mg/m3)
S1352-2310(18)30761-1
DOI:
https://doi.org/10.1016/j.atmosenv.2018.10.063
Reference:
AEA 16360
To appear in:
Atmospheric Environment
Received Date: 1 May 2018 Revised Date:
26 September 2018
Accepted Date: 29 October 2018
Please cite this article as: Karimi, B., shokrinezhad, B., Samadi, S., Mortality and hospitalizations due to cardiovascular and respiratory diseases associated with air pollution in Iran: A systematic review and meta-analysis, Atmospheric Environment (2018), doi: https://doi.org/10.1016/j.atmosenv.2018.10.063. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
ACCEPTED MANUSCRIPT Mortality and hospitalizations due to cardiovascular and respiratory diseases associated
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with air pollution in Iran: a systematic review and meta-analysis
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Behrooz Karimia,*, Behnosh shokrinezhada, Sadegh Samadib a
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6 Department of Environmental Health Engineering, Health Faculty, Arak University of Medical Sciences, Arak, b
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Iran; Department of Occupational Health, Health Faculty, Arak University of Medical Sciences, Arak, Iran;
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*Corresponding author; Behrooz Karimi; Department of Environmental Health Engineering, Health Faculty, Arak University of Medical Sciences, Arak, Iran Email: [email protected] Tel & Fax: +98 (0)863368443
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Air pollution is a major environmental health problem around the world. The purpose of this
21
study was to investigate the relationship between exposure to air pollution with mortality and
22
hospitalizations by conducting a systematic review and meta-analysis.
23
Several databases were searched for studies exploring the relationship between air pollution
24
and the all-cause, cardiovascular and respiratory mortality, as well as hospitalizations. The
25
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ABSTRACT
26
each study included. Random-effects model was applied to estimate the relative risks of all-
27
cause mortality and mortality/hospitalization due to cardiovascular and respiratory diseases.
28
We found a 0.6% (95% CI 0.5%-0.7%) increase in all-cause, 0.5% (95% CI 0.4%-0.6%)
29
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risk of bias assessed by the Office of Health Assessment and Translation (OHAT) Method for
30
per 10 µg/m3 increase of pooled all air pollutants. Moreover, we observed a 0.7% (95% CI
31
0.6%-0.9%) increase in hospitalization due to cardiovascular and respiratory diseases per 10
32
µg/m3 increase of pooled air pollutants. The highest all-cause mortality was associated with
33
exposure to particulates with aerodynamic diameters less than 2.5 µm (PM2.5) (681 deaths or
34
1.5%, 95% CI 1.3%-1.7%), followed by PM10 (253 deaths or 0.7%, 95% CI 0.6%-0.8%).
35
The current study illustrated that all investigated air pollutants were associated with elevated
36
mortality and hospitalization, but the effects of PM2.5 and PM10 were stronger. Thus,
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increase in cardiovascular, and 0.8% (95% CI 0.6%-0.9%) increase in respiratory mortality
authorities need to pay more attention to establishing the new regulations to apply control
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measures.
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Keywords: Mortality, Hospitalizations, Air pollution, Meta-analysis
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Systematic review registration: PROSPERO: CRD42018088770.
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Air pollution is a major environmental health problem around the world (Miri et al., 2016).
52
Rapid urbanization and industrialization are well-known causes of increasing air pollution
53
and subsequently associated with adverse health outcomes (Mannucci and Franchini, 2017;
54
Miri et al., 2016). Air pollution has become the 4th highest-ranking risk factor for death in the
55
world (Brauer, 2016). The world health organization (WHO) in 2016 reported that air
56
pollution of fine particles associated with 4.2 million deaths annually (WHO, 2018). In 2018,
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this figure increased to be 7 million deaths (WHO, 2018). More than 90% of air pollution-
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1. Introduction
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Africa. Regarding Middle East, the highest concentrations of air pollution are in the Eastern
60
Mediterranean Region and in South-East Asia, with annual mean concentrations often
61
exceeding more than 5 times WHO limits (WHO, 2018).
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According to the global ranking, Iran was ranked as the seventh among the most 10 top
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polluted countries (Heger and Sarraf, 2018). Tehran is ranked as 12th among 26
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related deaths reported to be occur in low- and middle-income countries, mainly in Asia and
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Additionally, Tehran as a capital city was the third most top polluted city in the world after
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Jakarta (Indonesia) and Kolkata (India) (Sefiddashti et al., 2015). Air pollution is a major
67
environmental risk factor for morbidity in Iran including diseases such as respiratory and
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megacities in terms of ambient PM10 concentrations (Heger and Sarraf, 2018).
cardiovascular diseases, lung cancer, Alzheimer’s and Parkinson’s diseases (Heger and
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Sarraf, 2018). The all-cause mortality attributed to air pollution in Tehran estimated to be
70
5388 deaths (40% of all deaths) in 2008 (Joneidi jafari et al., 2010) and this figure was
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elevated to be 5894 in 2017 (Mohammadi-Zadeh et al., 2017).
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The concentrations of carbon monoxide (CO), sulfur dioxide (SO2) and nitric oxide (NO) in
73
Tehran had downward trends during the years 2002-2017 (Arhami et al., 2017; Zarandi et al.,
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2015), while the concentrations of PM2.5, PM10, nitrogen dioxide (NO2) and ozone (O3) had
75
3
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respectively, about 3 and 4 times higher than the national standard limits in 2017
77
(Khodarahmi et al., 2016). Similarly, the concentrations of CO, SO2, NO, NO2 and O3 were
78
reported to be somewhat high as well (Ghozikali et al., 2016).
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The relationship between air pollution and mortality/hospitalizations in the countries has been
80
well-established (Atkinson et al., 2015; Khaniabadi et al., 2018; Rückerl et al., 2011).
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Numerous cohort studies suggesting a relationship between long-term exposure to air
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pollution and mortality in the world, especially with rapid urbanization and industrialization
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rising trends (Jaafari et al., 2017). The mean concentrations of PM2.5 and PM10 were,
84
2016; Fischer et al., 2015; Pope III et al., 2017). Traffic and combustion sources have been
85
previously associated with short-term cardiovascular and respiratory diseases (Bravo et al.,
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2017; Kim et al., 2012; Samoli et al., 2016). Moreover, there is increasing evidence of the
87
effects of PM with aerodynamic diameters less than 10 and 2.5 µm (PM10 and PM2.5) on
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cardiovascular disease and respiratory disease (Kloog et al., 2014; Lepeule et al., 2012; Lu et
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(Ancona et al., 2015; Beelen et al., 2014; Cesaroni et al., 2013; Chen et al., 2013; Chen et al.,
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associated with air pollution related to mortality and hospitalization in various Iranian cities.
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However, there is no complete and comprehensive analysis of these data, which together with
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their integration should generate the precious conclusion. Hence, we decided to do a
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al., 2015). Various studies have been carried out concerning the adverse health effects
systematic review and meta-analysis of these data. The objective of this review was to
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perform a systematic review and meta-analysis of the epidemiological studies to evaluate
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mortality and hospitalizations due to cardiovascular and respiratory diseases associated with
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air pollution in Iran.
97 98
2. Methods
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PROSPERO and is available at https:// www. crd. york. ac. uk/ PROSPERO/ display_record
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.asp ? ID=CRD42018088770. A complete PRISMA (Preferred Reporting Items for
102
Systematic Reviews and Meta-Analysis) checklist (Moher et al., 2015) is presented in the
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supplementary material (Table S1).
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The protocol information for present systematic review and meta-analysis were registered on
2.1. Study selection
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Two investigators (B.K and B.S) simultaneously searched the databases of PubMed,
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MagIran, IranMedex and Scientific Information Databank (SID). The databases were
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searched from January 1980 to January 2018 for studies investigating the all-cause mortality
110
as well as mortality and hospitalization relevant to cardiovascular and respiratory diseases
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which linked with exposure to air pollution. The following search keywords were used “air
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pollution”, “air pollutant”, “particulate”, “particles”, “PM10”, “PM2.5”, “carbon monoxide”,
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EMBASE, Web of Science, Scopus, Ovid, Google Scholar; and Iranian databases including
“CO”, “nitrogen dioxide”, “NO2”, “nitric oxide”, “nitrogen oxide”, “nitrogen monoxide”,
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“NO”, “sulfur dioxide”, “sulphur dioxide”, “SO2”, “ozone” or “O3” linked with “mortality”,
115
“cardiopulmonary
“hospital
116
admission” or “human health”. The reference lists of eligible articles were explored to find
117
“respiratory
mortality”,
“hospitalization”,
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mortality”,
the most relevant articles as well. Using PRISMA guidelines, article titles and abstracts were
118
first judged independently by two authors to choose the appropriate studies. The final
119
inclusion of studies was made on the basis of full article investigation. In cases of
120
uncertainties and inconsistency, the differences were resolved by a third author (SS).
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Publications were judged to be included in this review study if following inclusion criteria
122
applied: they reported a risk estimate for the relationship between exposure to air pollution
123
and all-cause mortality as well as mortality/hospitalization due to cardiovascular and
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5
ACCEPTED MANUSCRIPT respiratory diseases (Supplementary Table S2). Letters to the editor, systematic review
125
studies, and review studies were excluded.
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Information for each study was extracted by two authors independently, including the name
129
of the first author, study design, year of study, sample size, concentrations of air pollutants,
130
the main findings of mortality or hospitalization, latitude, province, city, and year of
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publication (Supplementary Table S1, Appendix A). The following extracted information for
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2.2. Data extraction
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pollutants, relative risk (RR) with 95% confidence interval (CI), numbers of all-cause
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mortality, as well as mortality/hospitalization due to cardiovascular and respiratory diseases.
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2.3. Risk of bias assessment
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the present review study was used: mean concentrations and standard deviations of air
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Sciences-National Toxicology program (NIEHS-NTP) and the Navigation Guide from the
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University of California, San Francisco (OHAT, 2015). The risks of bias were assessed for
141
following items: selection bias, confounders, exposure assessment, outcome assessment,
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Translation (OHAT) method presented by the National Institutes of Environmental Health
incomplete outcome data, selective reporting, and conflict of interest (Table 2 and more
143
analytically in Table S2 Appendix B and C). With regards to pre-specific criteria, the risk of
144
bias per each item was given as “low”, “probably low”, “probably high”, “high”, or “not
145
applicable”.
146 147
2.4. Data analysis
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6
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College Station, TX) and R software version 3.3.2 (R Core Team 2015). The heterogeneity of
150
studies was assessed by both Q test (P<0.10 as significant) and the coefficient of
151
inconsistency (I2). The value of I2 equals 25% indicating low heterogeneity and if it exceeds
152
75% suggesting high heterogeneity. Random-effects models and fixed-effect models were
153
applied to calculate the effect size of studies based on Mantel-Haenszel and DerSimonian
154
methods, respectively (DerSimonian and Laird, 1986). The pooled effect estimates of the
155
concentration of all air pollutants and the RR with 95% CI for mortality/hospitalization were
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Statistical analyses were performed with STATA software version 12 (STATA Corporation,
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were computed according to the following formula.
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calculated using the random-effects models. The percent changes in mortality/hospitalization
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The publication bias was examined by constructing funnel plots of the log risk ratio versus
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the standard error (SE). The source of heterogeneity was investigated by the application of
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meta-regression analysis for geographical latitude, year of study and sample size.
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Percent change (%) = (ln (RR-1)) × 100%
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and the causes of mortality and hospitalization. Begg’s and Egger’s tests were used for the
164
regression asymmetry test (P<0.10 as significant) and adjusted for publication bias following
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the “Trim and Fill” method if needed. Sensitivity analysis was performed to determine the
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Additionally, the subgroup analyses were performed by study design, type of air pollutants,
effect of removing each study.
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3. Results
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3.1. Included studies
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With a preliminary search of national and international databases, 1704 peer-reviewed studies
171
were identified. Of them, 197 articles were excluded because of the overlap between
172
databases. By reviewing the remaining articles, 1424 articles were removed since they were
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read and after a qualitative assessment, 45 articles were also excluded. Finally, 38 articles
175
were fulfilled the quality assessment criteria and they were included in this meta-analysis
176
(Fig. 1). Of which, 36 studies were cross-sectional and 2 time-series. Twenty four articles
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simultaneously examined both mortality and hospitalization, 2 studies only explored all-cause
178
mortality, 3 studies investigated mortality related to both cardiovascular and respiratory
179
diseases, and 4 studies explored hospitalization related to both cardiovascular and respiratory
180
diseases (Table 1). Table 2 shows the risk of bias for each selected study. Further details of
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unrelated to the aim of this study. The full texts of the remaining 83 articles were completely
182
Concerning the exposure assessment, the risk of bias was ‘low’ in the most of cases,
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‘probably low’ risk or ‘probably high’ risk in some cases, and only two studies had ‘high’
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risk.
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Table 1. Studies included in the meta-analysis
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individual studies are given in supplementary material (Table S2, Appendix B, and C).
186 187 188
Table 2. Risk of bias rating for each study.
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Fig.1. PRISMA flowchart for literature selection and study identification (Moher et al., 2015)
190 191
Table 3 provides the pooled mean concentrations of O3, PM2.5, PM10, NO2, NOx, SO2 and
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3.2. Concentrations of air pollutants
CO. As shown in Table 3, the pooled mean concentrations of CO and PM10 were the highest
193
exposure (2620 mg/m3 and 112.3 µg/m³), followed by NOx (95.9 µg/m³). The forest plots of
194
pooled concentrations of O3, PM2.5, PM10, NO2, NOx, SO2, and CO are given in
195
supplementary material (Figs. S1-4, Appendix C). Fig. 2 shows the mean concentration of
196
PM10 and the mean number of mortalities caused by PM10 derived from studies. The highest
197
concentrations of PM10 were observed in cities located in the western part of Iran.
198 199
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200
locations.
201 202
Table 3. Pooled mean concentrations of O3, PM2.5, PM10, NO2, NOx, SO2 and CO derived from studies.
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3.3. All-cause mortality
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in Table 3. The highest all-cause mortality was associated with exposure to PM2.5. The forest
207
plots of the association between all-cause mortality and exposure to O3, PM2.5, PM10, NO2,
208
NOx, SO2, CO are presented in supplementary material (Figs. S5-10, Appendix D). Using
209
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The association between the pooled amounts of all-cause mortality and air pollutants is given
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46.4 µg/m³ which was responsible for the high mortality rate (680 deaths), and PM10 with a
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pooled mean concentration of 112.3 µg/m³ attributed to the second highest mortality rate (253
212
deaths) (Table 4). An increasing of concentrations of PM10 and PM2.5 were associated with an
213
elevating of all-cause mortality after considering the quartile of mortality rate (Fig. 3 (A) and
214
(B)). The pooled percent changes for all-cause mortality rate in relation to exposure to all air
215
pollutants were 0.6% (95% CI 0.5%-0.7%). For all-cause mortality, the highest percent
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random-effects model, the results showed that the pooled mean concentration of PM2.5 was
217
changes in all-cause mortality rates with regard to the type of air pollutants are illustrated in
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change (1.5%, 95% CI 1.3%-1.7%) was related to PM2.5 exposure. The pooled percent
Fig. 4 (A).
219 220
Table 4. The pooled numbers of all-cause mortality related to O3, PM2.5, PM10, NO2, NOx, SO2 and CO.
221 222
Fig. 3. The association between (A) PM10 and (B) PM2.5 and number of all-cause mortality.
223 224
3.4. Cardiovascular mortality
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increase in all air pollutants. The same increase (0.5%, 95% CI 0.4%-0.6%) in cardiovascular
227
mortality per 10 µg/m3 increase in PM2.5 was observed as well. The highest percent change
228
increase in cardiovascular mortality (35.5%, 95% CI 8.5%-58.5%) was related to CO
229
exposure. The second highest percent change in cardiovascular mortality (0.8%, 95% CI
230
0.6%-1.0%) was related to SO2 exposure. The pooled percent changes in cardiovascular
231
mortality rates with regard to the type of air pollutants are illustrated in Fig. 4 (B). The
232
association between the pooled numbers of cardiovascular mortality and air pollutants is
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We obtained a 0.50% (95% CI 0.4%-0.6%) increase in cardiovascular mortality per 10 µg/m3
234
to O3, PM2.5, PM10, NO2, NOx, SO2, and CO are presented in supplementary material (Fig.
235
S11, Appendix D).
236
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given in Table 3. The forest plots of cardiovascular mortality rates associated with exposure
3.5. Respiratory mortality
237 238
pollutants are illustrated in Fig. 4(C). A 10 µg/m3 increase in all air pollutants corresponded
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The pooled percent changes in respiratory mortality rates with regard to the type of air
240
respiratory mortality (2.4%, 95% CI -5.8%-10.7%) was related to CO exposure, the second
241
highest percent change in respiratory mortality (1%, 95% CI, 0.6%-1.3%) was related to
242
PM10 exposure. The association between the pooled numbers of respiratory mortality and air
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to a 0.8% (95% CI 0.6%-0.9%) in respiratory mortality. The highest percent change in
pollutants is given in Table 3(C). Among all air pollutants, the highest respiratory mortality
244
rate was associated with exposure to PM2.5 (490 deaths). The forest plots of all-cause
245
mortality rates associated with exposure to O3, PM2.5, PM10, NO2, NOx, SO2, and CO are
246
presented in supplementary material (Fig. S12, Appendix D).
247 248
3.6. Hospitalization due to cardiovascular and respiratory diseases
10
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and respiratory diseases in relation to exposure to all air pollutants were 0.7% (95% CI 0.6%-
251
0.9%). The highest pooled percent change for hospitalization was related to CO exposure
252
(17.3%, 95% CI 3.0%-31.5%), and the second highest percent change was related to SO2
253
exposure (1.3%, 95% CI 0.1%-2.5%). The association between the pooled numbers of
254
hospitalization and air pollutants is given in Table 3 (D). Among all air pollutants, the highest
255
hospitalization was associated with exposure to PM2.5 (1558 cases), followed by PM10 (563
256
cases). The forest plots of hospitalization associated with exposure to O3, PM2.5, PM10, NO2,
257
NOx, SO2, and CO are presented in supplementary material (Fig. S13, Appendix D).
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As shown in Fig. 4(D), the pooled percent changes for hospitalization due to cardiovascular
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Fig. 4. Pooled percent changes in (A) all-cause, (B) cardiovascular and (C) respiratory mortality, and (D)
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hospitalization in relation to pooled concentrations of CO, NO2, O3, PM10, PM2.5, and SO2 with 95% CI.
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3.8. Additional analyses
262 263 264
significant source of heterogeneity (p<0.05), while the year of study and sample size were
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not. Funnel plot was slightly asymmetric and the result of Egger's test was significant
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Using a meta-regression model, the findings showed that only geographical latitude was a
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method showed that 57 studies required to obtain a full symmetry in Funnel plot (Q=421 and
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(p<0.001) (supplementary material, Figs. S14-16, Appendix D). Using the trim and fill
p<0.001) (supplementary material, Fig. S17, Appendix D). The sensitivity analysis test
269
showed that there was no significant change in the results (supplementary material, Fig. S18,
270
Appendix E).
271 272
4. Discussion
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The results of this study showed a significant relationship between mortality and
274
hospitalization with exposure to air pollutants of O3, PM2.5, PM10, NO2, NOx, SO2, and CO.
275
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60.1, 46.4, 112.3, 58.0, 95.9 and 34.8 µg/m³. Among these air pollutants, the pooled mean
277
concentration of PM10 (112.3 µg/m3) was the highest exposure and this concentration was
278
2.26 times greater than the concentration (50 µg/m3) suggested by the WHO guideline (Miri
279
et al., 2016). The pooled mean concentration of PM2.5 (46.4 µg/m3) was 1.85 times greater
280
than the concentration (25 µg/m³) proposed by WHO guideline (Miri et al., 2016). Beelen et
281
al. in a study found that a concentration of about 20 µg/m³ of PM2.5, slightly lower than the
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concentration (25 µg/m³) suggested by WHO guideline, associated with an increased risk of
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The pooled mean concentrations for O3, PM2.5, PM10, NO2, NOx, and SO2 were, respectively;
284
considerably high concentrations of PM2.5 and PM10 (Goudarzi et al., 2017; Goudarzi et al.,
285
2015b; Shahsavani et al., 2012). Shahsavani et al. in a study found substantially higher
286
concentrations of PM10 (319.6 ± 407 µg/m3) and PM2.5 (69.5 ± 83.2 µg/m3) (Shahsavani et
287
al., 2012). Similarly, Goudarzi et al. in two studies measured a remarkably high concentration
288
of PM10 which was probably related to dust storms (in respectively 261 and 360 µg/m3)
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mortality (Beelen et al., 2014). Three studies we included in this meta-analysis, they reported
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concentrations of PM2.5 and PM10 reported by these 3 studies could be contributed to high
291
pooled concentrations of PM2.5 and PM10 observed in this meta-analysis. In agreement with
292
remarkably high pooled concentrations of PM2.5 and PM10 in this review, a study carried out
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(Goudarzi et al., 2017; Goudarzi et al., 2015b). Thus, findings of considerably high
by Draxler et al. in countries located in the west and south of Iran, the concentrations of
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PM10 reported to be very high (3000 µg/m3) (Draxler et al., 2001). However, this
295
concentration was almost 27 times higher than the pooled mean concentration of PM10
296
obtained from this study. Meng and Lu found that the mean concentration of PM2.5 was 217
297
µg/m3 (Meng and Lu, 2007) which were 4 times higher than the pooled mean concentration
298
of PM2.5 in the present study. These findings proposed that probably dust storms in this meta-
299
analysis could be an important source of high concentrations of PM10. The other possible
300
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close to cities.
302
We observed an association between the increasing concentration of PM2.5 and the elevating
303
risks of the all-cause, cardiovascular and respiratory mortality. In parallel to our findings,
304
Beelen et al. reported that the most cases of mortality due to particulate matter were related to
305
PM2.5, while coarse particles had less effect (Beelen et al., 2014). The same results were also
306
reported in nurses’ health study (Puett et al., 2009). The association between the percent
307
changes in all-cause, cardiovascular and respiratory mortality and PM10 and PM2.5 for 10-
308
µg/m3 increase in this study has been compared with other studies in Table 5.
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sources could be particulate matters released from cars as well as industries which located
310
Table 5. The percent change of all-cause, cardiovascular and respiratory mortality (95% CI) for a 10-µg/m3
311
increase in the average concentration of PM10 and PM2.5 in this study compared with other studies
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We found that the pooled RR of all-cause mortality based on 10 µg/m³ increase of PM2.5 was
313 314 315
the RRs of mortality from long-term exposure to PM2.5 were 1.04, 1.06, and 1.13,
316
respectively; which were slightly higher than our results (Ballester et al., 2008; Beelen et al.,
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1.015. Three studies conducted by Ballester et al., Pope et al. and Beelen et al. showed that
318
Society Study on Los Angeles population reported being much higher (Jerrett et al., 2005).
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2014; Pope III et al., 2002). The RR of mortality (1.17) related to PM2.5 exposure in cancer
In the present study, the health effects reported by studies differed. The discrepancy in
320
relation to the estimating of the health effects between studies might be explained by different
321
definitions used for health effects. Other factors such as population size, sources of air
322
pollution, the intensity of exposure, and the components of PMs might be responsible for
323
observed health effects. The underlying mechanisms of health effects associated with PMs
324
are poorly understood. Nonetheless, PMs are well-known causing biochemical stresses such
325
as systemic inflammation and oxidative stress (Møller et al., 2014). Chronic inflammation
326
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known as indicators of the biological aging of cells (Karimi et al., 2017). To confirm this,
328
McCracken et al. in a study among the elderly population found that the prolonged exposure
329
to PM in high traffic areas associated with a shortened length of telomere (McCracken et al.,
330
2010).
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and oxidative stress are associated with shortened telomeres, and subsequently, they are
332
1.001–1.004), which was lower than those RR values reported by Beelen et al. (1.01, 95% CI
333
0.99–1.03) and Mills et al. (1.007, 95% CI 1.004–1.010) (Beelen et al., 2014; Mills et al.,
334
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In the present study, the RR value for all-cause mortality due to NO2 was 1.003 (95% CI
335
respiratory diseases such as asthma and subsequently the number of hospitalizations due to
336
respiratory diseases increased (Mohammadi et al., 2016). Since most of the Iranian people
337
often use their own cars, the high exposure to NO2 in the present study could be explained by
338
the high number of cars used and also the intense traffic jam.
339
The trend of O3 concentration in Iran has been steadily increased over the last two decades,
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2015) A study reported that exposures to NO2 were associated with the prevalence increase of
341
elevated concentration of 10 µg/m3 of O3 resulted in an increase of 0.4% in all-cause
342
mortality. This finding was roughly close to those results reported by four studies: a meta-
343
analysis study conducted by WHO (0.3%), a systematic review of Chinese studies (0.48%),
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with higher concentrations in the warm seasons (Zarandi et al., 2015). We revealed that the
the Chinese PAPA study (0.31%), and a Canadian cohort study with a follow-up of 16 years
345
(0.34%)(Anderson et al., 2004; Crouse et al., 2015; Shang et al., 2013; Wong et al., 2008). In
346
contrast, Carey et al. and Ghorbani et al. observed a negative relationship between the annual
347
mean concentration of O3 and the mortality rate (both RR=0.98) (Carey et al., 2013;
348
Ghorbani et al., 2017).
349
Among the air pollutants, an increase of 10 mg/m3 in CO concentration was significantly
350
associated with an elevated RR of hospitalization (1.173, 95% CI 1.030–1.315). Zheng et al.
351
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findings found that the RR of hospitalization related to CO exposure was 1.045 (95% CI
353
1.029-1.061) which was somewhat lower than our RR value, while a considerably higher RR
354
(1.490, 95% CI 1.250-1.770) was found by Shahi et al. (Shahi et al., 2014). The mechanism
355
of health effects related to CO is poorly understood. Nonetheless, CO quickly bonds with
356
hemoglobin and interferes with oxygen release in tissues. Then, cardiovascular dysfunction
357
includes myocardial infarction, arrhythmia and angina could occur (Lee et al., 2015).
358
The estimates derived from this study could be applied to health risk assessments of air
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(Zheng et al., 2015) in a systematic review and meta-analysis study in accordance of our
360
effectively synthesize existing data of all types and design data collection efforts in a variety
361
of research contexts. However, evidence of mortality and hospitalizations, especially for
362
chronic obstructive pulmonary disease (COPD) and myocardial infarction, is still insufficient
363
for meta-analysis.
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5. Conclusions
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pollutants in Iran and a meta-analysis is a versatile tool that can help researchers more
365 366 367
associated with air pollution in Iran. All investigated air pollutants were associated with
368
increased risk of mortality and hospitalization due to cardiovascular and respiratory diseases,
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This is the first systematic review and meta-analysis of mortality and hospitalization
but the effects of PM2.5 and PM10 were stronger. So identifying the concentrations and
370
sources of air pollutants will help to establish the new regulations for control measures. This
371
subsequently leads to the diminishing of mortality and hospitalization. Moreover, further
372
cohort-based studies in this field are needed to be conducted to better investigate the effects
373
of air pollution on health effects.
374 375
Acknowledgments: This study was supported by Arak University of Medical Sciences, Iran. The authors will
376
like to thank Dr. Masoud Behzadfar for providing us the additional analyses.
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ACCEPTED MANUSCRIPT 378 Supplementary data
379
Supplementary data to this article can be found in Tables S1-2 and Figs S1-18.
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Ancona, C., Badaloni, C., Mataloni, F., Bolignano, A., Bucci, S., Cesaroni, G., Sozzi, R., Davoli, M., Forastiere, F., 2015. Mortality and morbidity in a population exposed to multiple sources of air pollution: A retrospective cohort study using air dispersion models. Environmental research 137, 467-474. Anderson, H.R., Atkinson, R.W., Peacock, J., Marston, L., Konstantinou, K., Organization, W.H., 2004. Meta-analysis of time-series studies and panel studies of particulate matter (PM) and ozone (O3): report of a WHO task group. Arhami, M., Hosseini, V., Shahne, M.Z., Bigdeli, M., Lai, A., Schauer, J.J., 2017. Seasonal trends, chemical speciation and source apportionment of fine PM in Tehran. Atmospheric Environment 153, 70-82. Atkinson, R.W., Mills, I.C ,.Walton, H.A., Anderson, H.R., 2015. Fine particle components and health—a systematic review and meta-analysis of epidemiological time series studies of daily mortality and hospital admissions. Journal of Exposure Science and Environmental Epidemiology 25 , .208 Bahrami Asl, F., Kermani, M., Aghaei, M., Karimzadeh, S., Salahshour Arian, S., Shahsavani, A., Goudarzi, G., 2015. Estimation of Diseases and Mortality Attributed to NO2 pollutant in five metropolises of Iran using AirQ model in 2011-2012. Journal of Mazandaran University of Medical Sciences 24, 239-249. Ballester, F., Medina, S., Boldo, E., Goodman, P., Neuberger, M., Iñiguez, C., Künzli, N., 2008. Reducing ambient levels of fine particulates could substantially improve health: a mortality impact assessment for 26 European cities. Journal of Epidemiology & Community Health 62, 98-105. Beelen, R., Raaschou-Nielsen, O., Stafoggia, M., Andersen, Z.J., Weinmayr, G., Hoffmann, B., Wolf, K., Samoli, E., Fischer, P., Nieuwenhuijsen, M., 2014. Effects of long-term exposure to air pollution on natural-cause mortality: an analysis of 22 European cohorts within the multicentre ESCAPE project. The Lancet 383, 785-795. Brauer, M., 2016. The global burden of disease from air pollution, 2016 AAAS Annual Meeting (February 11-15, 2016). aaas. Bravo, M.A., Ebisu, K., Dominici, F., Wang, Y., Peng, R.D., Bell, M.L., 2017. Airborne fine particles and risk of hospital admissions for understudied populations: effects by urbanicity and short-term cumulative exposures in 708 US counties. Environmental health perspectives 125, 594. Carey, I.M., Atkinson, R.W., Kent, A.J., Van Staa, T., Cook, D.G., Anderson, H.R., 2013. Mortality associations with long-term exposure to outdoor air pollution in a national English cohort. American journal of respiratory and critical care medicine 187, 1226-1233. Cesaroni, G., Badaloni, C., Gariazzo, C., Stafoggia, M., Sozzi, R., Davoli, M., Forastiere, F., 2013. Longterm exposure to urban air pollution and mortality in a cohort of more than a million adults in Rome. Environmental health perspectives 121, 324. Chen, H., Goldberg, M.S., Burnett, R.T., Jerrett, M., Wheeler, A.J., Villeneuve, P.J., 2013. Long-term exposure to traffic-related air pollution and cardiovascular mortality. Epidemiology 24, 35-43. Chen, X., Zhang, L.-w., Huang, J.-j., Song, F.-j., Zhang, L.-p., Qian, Z.-m., Trevathan, E., Mao, H.-j., Han, B., Vaughn, M., 2016. Long-term exposure to urban air pollution and lung cancer mortality: A 12-year cohort study in Northern China. Science of The Total Environment 571, 855-861. Crouse, D.L., Peters, P.A., Hystad, P., Brook, J.R., van Donkelaar, A., Martin, R.V., Villeneuve, P.J., Jerrett, M., Goldberg, M.S., Pope III, C.A., 2015. Ambient PM2. 5, O3, and NO2 exposures and
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Hosseini, G., Maleki, A., Amini, H., Mohammadi, S., Hassanvand, M.S., Giahi, O., Gharibi, F., 2014. Health impact assessment of particulate matter in Sanandaj, Kurdistan, Iran. Journal of Advances in Environmental Health Research 2. Jaafari, J., Naddafi, K., Yunesian, M., Nabizadeh, R., Hassanvand, M.S., Ghozikali, M.G., Nazmara, S., Shamsollahi, H.R., Yaghmaeian, K., 2017. Study of PM10, PM2. 5, and PM1 levels in during dust storms and local air pollution events in urban and rural sites in Tehran. Human and Ecological Risk Assessment: An International Journal, 1-12. Jerrett, M., Burnett, R.T., Ma, R., Pope III, C.A., Krewski, D., Newbold, K.B., Thurston, G., Shi, Y., Finkelstein, N., Calle, E.E., 2005. Spatial analysis of air pollution and mortality in Los Angeles. Epidemiology 16, 727-736. Joneidi jafari, Zohor A, Rezaie R, Malekafzali Sh, A, S., 2010. Estimation of hearty and respiration dead by air pollution of Tehran city based on particulate matter Teb and tazkie journal 74-75, 37-47 Karimi, B., Nabizadeh, R., Yunesian, M., Mehdipour, P., Rastkari, N., Aghaie, A., 2017. Foods, Dietary Patterns and Occupational Class and Leukocyte Telomere Length in the Male Population. American journal of men's health, 1557988317743385. Kermani, M., Aghaei, M., 2016. Estimation of cardiovascular death, myocardial infarction and chronic obstructive pulmonary disease) COPD) attributed to PM and SO2 in the air of Tehran metropolis. Journal of Research in Environmental Health 2, 116-126. Kermani, M., Aghaei, M., Dolati, M., 2016a. Estimation the Number of Mortality Due to Cardiovascular and Respiratory disease, Attributed to pollutants O3, and NO2 in the Air of Tehran. Journal of health research in community 1, 1-11. Kermani, M., Aghaei, M., Gholami, M., Asl, F., Karimzadeh, S., Jokandan, S., Dowlati, M., 2016b. Estimation of mortality attributed to PM2. 5 and CO exposure in eight industrialized cities of Iran during 2011. Iran Occupational Health 13, 49-61. Kermani, M., Bahrami Asl, F., Aghaei, M., Karimzadeh, S., Arfaeinia, H., Godarzi, G., Salahshour Arian, S., 2015. Quantification of Health Effects Attributed to Ozone in Five Metropolises of Iran Using AirQ Model. Journal of Health 6, 266-280. Khamutian, R., Sharafi, K., Najafi, F., Shahhoseini, M., 2014. Association of Air Pollution and Hospital Admission for Cardiovascular Disease: A. Khaniabadi, Y.O., Goudarzi, G ,.Daryanoosh, S.M., Borgini, A., Tittarelli, A., De Marco, A., 2017a. Exposure to PM10, NO2, and O3 and impacts on human health. Environmental Science and Pollution Research 24, 2781-2789. Khaniabadi, Y.O., Hopke, P.K., Goudarzi, G., Daryanoosh, S.M., Jourvand, M., Basiri, H., 2017b. Cardiopulmonary mortality and COPD attributed to ambient ozone. Environmental research 152, 336-341. Khaniabadi, Y.O., Sicard, P., Takdastan, A., Hopke, P.K., Taiwo, A.M., Khaniabadi, F.O., De Marco, A., Daryanoosh, M., 2018 .Mortality and morbidity due to ambient air pollution in Iran. Clinical Epidemiology and Global Health. Khanjani, N., Ranadeh Kalankesh, L., Mansouri, F., 2012. Air pollution and Respiratory Deaths in Kerman, Iran (from 2006 till 2010). Iranian Journal of Epidemiology 8, 58-65. Khodarahmi, F., Soleimani, Z., Yousefzadeh, S., Alavi, N., Babaei, A.A., Mohammadi, M.J., Goudarzi, G., 2016. Levels of PM10, PM2. 5 and PM1 and Impacts of Meteorological Factors on Particle Matter Concentrations in Dust Events and non Dusty Days. International Journal of Health Studies 1, page: 7-12. Kim, S.-Y., Peel, J.L., Hannigan, M.P., Dutton, S.J., Sheppard, L., Clark, M.L., Vedal, S., 2012. The temporal lag structure of short-term associations of fine particulate matter chemical constituents and cardiovascular and respiratory hospitalizations. Environmental health perspectives 120, 1094. Kloog, I., Nordio, F., Zanobetti, A., Coull, B.A., Koutrakis, P., Schwartz, J.D., 2014. Short term effects of particle exposure on hospital admissions in the Mid-Atlantic states: a population estimate. PloS one 9, e88578.
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Lee, F.-Y., Chen, W.-K., Lin, C.-L., Kao, C.-H., 2015. Carbon monoxide poisoning and subsequent cardiovascular disease risk: a nationwide population-based cohort study. Medicine 94. Lepeule, J., Laden, F., Dockery, D., Schwartz, J., 2012. Chronic exposure to fine particles and mortality: an extended follow-up of the Harvard Six Cities study from 1974 to 2009. Environmental health perspectives 120, 965. Lu, F., Xu, D., Cheng ,Y., Dong, S., Guo, C., Jiang, X., Zheng, X., 2015. Systematic review and metaanalysis of the adverse health effects of ambient PM2. 5 and PM10 pollution in the Chinese population. Environmental research 136, 196-204. Mannucci, P.M., Franchini, M., 2017 .Health effects of ambient air pollution in developing countries. International journal of environmental research and public health 14, 1048. Marzouni, M.B., Alizadeh, T., Banafsheh, M.R., Khorshiddoust, A.M., Ghozikali, M.G., Akbaripoor, S., Sharifi, R ,.Goudarzi, G., 2016. A comparison of health impacts assessment for PM 10 during two successive years in the ambient air of Kermanshah, Iran. Atmospheric Pollution Research 7, 768-774. McCracken, J., Baccarelli, A., Hoxha, M., Dioni, L., Melly, S., Coull ,B., Suh, H., Vokonas, P., Schwartz, J., 2010. Annual ambient black carbon associated with shorter telomeres in elderly men: Veterans Affairs Normative Aging Study. Environmental health perspectives 118, 1564. Meng, Z., Lu, B., 2007. Dust events as a risk factor for daily hospitalization for respiratory and cardiovascular diseases in Minqin, China. Atmospheric Environment 41, 7048-7058. Mills, I.C., Atkinson, R.W., Kang, S., Walton, H., Anderson, H., 2015. Quantitative systematic review of the associations between short-term exposure to nitrogen dioxide and mortality and hospital admissions. BMJ open 5, e006946. Miri, M., Derakhshan, Z., Allahabadi, A., Ahmadi, E., Conti, G.O., Ferrante, M., Aval, H.E., 2016. Mortality and morbidity due to exposure to outdoor air pollution in Mashhad metropolis, Iran. The AirQ model approach. Environmental research 151, 451-457. Mohammadi-Zadeh, M.J., Karbassi, A., Bidhendi, G.N., Abbaspour, M., Padash, A., 2017. An Analysis of Air Pollutants’ Emission Coefficient in the Transport Sector of Tehran. Open Journal of Ecology 7, 309. Mohammadi, A., Azhdarpoor, A., Shahsavani, A., Tabatabaee, H., 2015. Health Impacts of Exposure to PM 10 on Inhabitants of Shiraz, Iran. Health Scope 4. Mohammadi, A., Azhdarpoor, A., Shahsavani ,A., Tabatabaee, H., 2016. Investigating the health effects of exposure to criteria pollutants using AirQ2. 2.3 in Shiraz, Iran. Aerosol and Air Quality Research 16, 1035-1043. Moher, D., Shamseer, L., Clarke, M., Ghersi, D., Liberati, A., Petticrew, M ,.Shekelle, P., Stewart, L.A., 2015. Preferred reporting items for systematic review and meta-analysis protocols (PRISMA-P) 2015 statement. Systematic reviews 4, 1. Mokhtari, M., Miri, M., Mohammadi, A., Khorsandi, H., Hajizadeh, Y., Abdolahnejad, A., 2015 . Assessment of air quality index and health impact of PM10, PM2. 5 and SO2 in Yazd, Iran. Journal of Mazandaran University of Medical Sciences 25, 14-23. Møller, P., Danielsen, P.H., Karottki, D.G., Jantzen, K., Roursgaard, M., Klingberg, H., Jensen, D.M ,. Christophersen, D.V., Hemmingsen, J.G., Cao, Y., 2014. Oxidative stress and inflammation generated DNA damage by exposure to air pollution particles. Mutation Research/Reviews in Mutation Research 762, 133-166. Naddafi, K., Hassanvand, M.S., Yunesian, M ,.Momeniha, F., Nabizadeh, R., Faridi, S., Gholampour, A., 2012. Health impact assessment of air pollution in megacity of Tehran, Iran. Iranian journal of environmental health science & engineering 9, 28. Nikoonahad, A., Naserifar, R., Alipour, V., Poursafar, A., Miri, M., Ghafari, H.R., Abdolahnejad, A., Nemati, S., Mohammadi, A., 2017. Assessment of hospitalization and mortality from exposure to PM10 using AirQ modeling in Ilam, Iran. Environmental Science and Pollution Research 24, 2179121796.
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Nourmoradi, H., Goudarzi, G., Daryanoosh, S.M., Omidi-Khaniabadi, F., Jourvand, M., OmidiKhaniabadi, Y., 2015. Health Impacts of Particulate Matter in Air using AirQ Model in Khorramabad City, Iran. Journal of Basic Research in Medical Sciences 2, 44-52. Nourmoradi, H., Khaniabadi, Y.O., Goudarzi, G., Daryanoosh, S.M., Khoshgoftar, M., Omidi, F., Armin, H., 2016. Air quality and health risks associated with exposure to particulate matter: a crosssectional study in Khorramabad, Iran. Health Scope 5. OHAT, 2015 .Handbook for Conducting a Literature-Based Health Assessment Using OHAT Approach for Systematic Review and Evidence Integration. Office of Health Assessment and Translation, Division of National Toxicology Program, National Institute of Environmental Health Sciences. Omidi, Y., Goudarzi, G., Heidari, A.M., Daryanoosh, S.M., 2016. Health impact assessment of shortterm exposure to NO2 in Kermanshah, Iran using AirQ model. Environmental Health Engineering and Management Journal. Pope III, C.A., Burnett, R.T., Thun, M.J., Calle, E.E., Krewski, D., Ito, K., Thurston, G.D., 2002. Lung cancer, cardiopulmonary mortality, and long-term exposure to fine particulate air pollution. Jama 287, 1132-1141. Pope III, C.A., Krewski, D., Gapstur, S.M., Turner, M.C., Jerrett, M., Burnett, R.T., 2017. Fine Particulate Air Pollution and Mortality: Response to Enstrom’s Reanalysis of the American Cancer Society Cancer Prevention Study II Cohort. Dose-Response 15, 1559325817746303. Puett, R.C., Hart, J.E., Yanosky, J.D., Paciorek, C., Schwartz, J., Suh, H., Speizer, F.E., Laden, F., 2009. Chronic fine and coarse particulate exposure, mortality, and coronary heart disease in the Nurses’ Health Study. Environmental health perspectives 117, 1697. Rückerl, R., Schneider, A., Breitner, S., Cyrys, J., Peters, A., 2011. Health effects of particulate air pollution: a review of epidemiological evidence. Inhalation toxicology 23, 555-592. Samoli, E., Atkinson, R.W., Analitis, A., Fuller, G.W., Green, D.C., Mudway, I., Anderson, H.R., Kelly, F.J., 2016. Associations of short-term exposure to traffic-related air pollution with cardiovascular and respiratory hospital admissions in London, UK. Occup Environ Med, oemed-2015-103136. Sefiddashti, S.E., Sari, A.A., Ghazanfa, S., 2015. The Impact of Air Pollution on Emergency Admissions of Heart Attack Cases in Tehran: 2007-2012. Journal of Health and Development 4, 190-199. Shahi, A.M., Omraninava, A., Goli, M., Soheilarezoomand, H.R., Mirzaei, N., 2014. The effects of air pollution on cardiovascular and respiratory causes of emergency admission. Emergency 2, 107. Shahsavani, A., Naddafi, K., Haghighifard, N.J., Mesdaghinia, A., Yunesian, M., Nabizadeh, R., Arahami, M., Sowlat, M., Yarahmadi, M., Saki, H., 2012. The evaluation of PM 10, PM 2.5 ,and PM 1 concentrations during the Middle Eastern Dust (MED) events in Ahvaz, Iran, from April through September 2010. Journal of Arid Environments 77, 72-83. Shang, Y., Sun, Z., Cao, J., Wang, X., Zhong, L., Bi, X., Li, H., Liu, W., Zhu, T., Huang, W .2013 ,. Systematic review of Chinese studies of short-term exposure to air pollution and daily mortality. Environment international 54, 100-111. WHO (World Health Organization), 2018. World Health Organization releases new global air pollution data. Geneva, Switzerland. http://www.ccacoalition.org/en/news/world-healthorganization-releases-new-global-air-pollution-data [accessed 26 September 2018]. Wong, C.-M., Vichit-Vadakan, N., Kan, H., Qian, Z., 2008. Public Health and Air Pollution in Asia (PAPA): a multicity study of short-term effects of air pollution on mortality. Environmental health perspectives 116, 1195. Zallaghi, E., 201 .4Assessment of health impacts attributed to PM10 exposure during 2011 in Kermanshah City, Iran. Journal of Advances in Environmental Health Research 2. Zallaghi, E., Geravandi, S., Haddad, M.N., Goudarzi, G., Valipour, L., Salmanzadeh, S., Hashemzadeh , B., Zahedi, A., Mohammadi, M.J., Soltani, F., 2015. Estimation of health effects attributed to nitrogen dioxide exposure using the AirQ model in Tabriz City, Iran. Health Scope 4. Zallaghi, E., Goudarzi, G., Geravandi, S., Mohammadi, M.J., 2014. Epidemiological indexes attributed to particulates with less than 10 micrometers in the air of Ahvaz City during 2010 to 2013. Health Scope 3.
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ACCEPTED MANUSCRIPT Table 1. Studies included in the meta-analysis. Type of study Cross- sectional
Pollutants O3
Kerman, 2006 - 2010
Time series
3
(Mokhtari et al., 2015)
Yazd, 2013-2014
ecological
PM10, CO, NO, NO2, NOx, O3, SO2 PM10, PM2.5, SO2
4
(Daryanoosh et al., 2017)
Ahvaz, Khorramabad, Ilam
Cross- sectional
PM10
5
(Goudarzi et al., 2015b)
Ahvaz, during 2009
Cross- sectional
PM10
6
(Kermani et al., 2015)
Cross-sectional
O3
7
(Kermani et al., 2016b)
Mashhad, Tabriz, Shiraz, Isfahan and Arak, 2011. 8 industrial cities of Iran, 2011
Cross-sectional
PM2.5, CO
8
(Kermani and Aghaei, 2016)
Tehran, 2012
Cross-sectional
PM10, PM2.5, SO2
9
(Ghorbani et al., 2017)
Mashhad, 2012
Cross-sectional
10
(Kermani et al., 2016a)
Tehran, 2014
CO, SO2, NOx, NO2, NO, O3 NO2, O3
11 12
(Ghozikali et al., 2016) (Miri et al., 2016)
Tabriz, 2011–2012 Mashhad, 2012
13 14 15 16 17 18 19
(Goudarzi et al., 2017) (Shahsavani et al., 2012) (Marzouni et al., 2016) (Omidi et al., 2016) (Goudarzi et al., 2015a) (Khaniabadi et al., 2017a) (Nikoonahad et al., 2017)
Kermanshah, 2014 - 2015 Ahvaz, 2010 Kermanshah, 2011- 2012 Kermanshah Ahvaz Kermanshah, 2014– 2015 Ilam, 2014–2015
Cross- section Cross- section Cross- section Cross- section Cross-sectional Cross-sectional Cross-sectional
20 21 22 23 24 25 26 27
(Mohammadi et al., 2016) (Naddafi et al., 2012) (Gholampour et al., 2014) (Zallaghi et al., 2014) (Mohammadi et al., 2015) (Khaniabadi et al., 2017b) (Bahrami Asl et al., 2015) (Dadbakhsh et al., 2015)
Shiraz, 2012 Tehran, 2012 Tabriz, 2012 - 2013 Ahvaz 2010 - 2013 Shiraz, 2013 Kermanshah, 2014 - 2015 five metropolises, 2011-2012 Shiraz, 2006-2012
Cross-sectional Cross-sectional Cross-sectional Cross-sectional Cross-sectional Cross-sectional Cross-sectional Cross-sectional
28 29 30 31 32 33 34 35 36 37
(Nourmoradi et al., 2015) (Hosseini et al., 2014) (Geravandi et al., 2016) (Goudarzi et al., 2012) (Zallaghi, 2014) (Geravandi et al., 2015) (Zallaghi et al., 2015) (Nourmoradi et al., 2016) (Gharehchahi et al., 2013) (Shahi et al., 2014)
Khorramabad, 2014 Sanandaj, Kurdistan, 2013 Ahvaz 2011 Ahvaz 2009 Kermanshah 2011 Ahwaz, Bushehr, Kermanshah, 2011 Tabriz, 2015 Khorramabad Shiraz, 2008-2010 Tehran, 2012
Cross-sectional Cross-sectional Cross-sectional Cross-sectional Cross-sectional Cross-sectional Cross-sectional Cross-sectional Cross-sectional Time series
38
(Khamutian et al., 2014)
Kermanshah, 2010-2011
Cross-sectional
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Location/Period Tabriz, Iran: 2014
2
Study (Ghanbari Ghozikali et al., 2014) (Khanjani et al., 2012)
Cross-sectional
Cross-sectional Cross- section
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O3, SO2 NO2 PM10, PM2.5, O3, NO2, SO2 PM10 PM10, PM2.5 PM10 NO2, O3 O3 PM10, NO2, O3 PM10 PM10, SO2, NO2, O3 O3, NO2, PM10, SO2 PM2.5, PM10 PM10 PM10 O3 NO2 O3, SO2, CO, PM10, NO, NO2, NOx PM10 PM10 O3 NO2 PM10 PM10, NO2 NO2 PM10 PM10, SO2, NO2 O3, NO2, SO2, PM10, PM2.5, CO NO, PM10, CO, O3, SO2
ACCEPTED MANUSCRIPT Table 2. Risk of bias rating for each study
23 24 25
Zallaghi et al. 2010
26 27 28
Bahrami et al. 2011
29 30
Hosseini et al. 2014
31
Goudarzi et al. 2011
32 33 34 35
Zallaghi et al. 2009
36
Gharehchahi et al. 2008
37
Shahi et al. 2012
Omidi et al. 2014 Goudarzi et al. 2012 Omidi et al. 2014 Nikoonahad et al. 2014 Mohammadi et al. 2012 Naddafi et al. 2012
Selection bias
Incomplete outcome data
Selective outcome reporting
Conflict of interest
Other
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Dadbakhsh et al. 2009 Nourmoradi et al. 2006
Confounding
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Ghanbari et al. 2014 Khanjani et al. 2014 Mokhtari et al. 2013 Daryanoosh et al. 2014 Goudarzi et al. 2009 Kermani et al. 2011 Kermani et al. 2011 Kermani et al. 2013 Ghorbaniet al. 2011 Kermani et al. 2014 Ghanbari et al. 2011 Miri et al. 2015 Goudarzi et al. 2014 Shahsavani et al. 2010 Bagherian et al. 2011
Outcome assessment
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Exposure assessment
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Geravandi et al. 2013
Geravandi et al. 2011 Zallaghi et al. 2012
Nourmoradi et al. 2015
38 Khamutian et al. 2010 Risk of bias rating
Low
Probably Low
Probably high
High
ACCEPTED MANUSCRIPT
Table 3. Pooled mean concentrations of O3, PM2.5, PM10, NO2, NOx, SO2 and CO derived from studies.
O3 PM2.5 PM10 NO2 NOx SO2 CO
mean
lower
upper
Standard
Heterogeneity
df
P
I-squared
Tau-squared
60.1 46.4 112.3 57.9 95.8 34.8
45.7 31.3 73.0 46.4 24.1 19.7
74.4 61.5 151.6 69.5 167.6 49.8
2620.3
1569.1
3672.6
159 35 150 100 196 10000
66.5 2.3 89.9 28.1 0.41 28.8 5.7
19 14 26 20 2 12 5
0.00 1 0.00 0.10 0.80 0.004 0.34
71.40% 0.00% 71.10% 11.90% 0.00% 58.30% 89.70%
479.9 0 5500 0.16 0 296.8 201.8
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Pollutants
Heterogeneity
df
P
I-squared
Tau-squared
273.5 178.6 871.0 267.6 242.8 92.4 4.8 72.8
3898.1 3.6 834.3 15597.8 1930.2 650.9 56.6 34822.1
47 3 15 98 22 22 7 227
0 0.312 0 0 0 0 0 0
98.8% 15.9% 98.2% 99.4% 98.9% 96.6% 87.6% 99.3%
13000 768.1665 140000 3300 9500 898.475 3.6099 114.7866
297.3 187.1 140.7 4.8 281.4 335.5 28.2
779.7 1428.4 174.6 56.6 714.6 6970.9 12951.7
13 18 6 7 8 2 61
0 0 0 0 0 0 0
98.3% 98.7% 96.6% 87.6% 98.9% 100.0% 99.5%
2.40E+04 2.00E+03 2.20E+03 3.6099 1.30E+04 77.235 44.0957
259.3 53.6 50.5 430.5 812.0 86.4
492.7 830.5 129.7 3.8 0.0 2202.0
13 18 6 1 0 44
0 0 0 0.052 . 0
97.4% 97.8% 95.4% 73.5% .% 98.0%
6.80E+03 276.4695 320.9848 7.80E+03 0 570.446
381.9 645.6 244.7 768.9 2485.5 398.2
431.0 8851.2 401.4 40.8 0.0 10918.4
7 41 5 3 0 64
0 0 0 0 . 0
98.4% 99.5% 98.8% 92.6% .% 99.4%
2.70E+04 6.20E+04 1.90E+04 1.10E+05 0 1.70E+04
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Pollutants mean lower A) All-cause mortality O3 236.8 200.1 TSP 114.0 49.5 PM2.5 680.5 490.1 PM10 252.9 238.2 NO2 199.2 155.5 SO2 76.5 60.5 CO 3.0 1.3 Overall 70.1 67.5 B) Cardiovascular mortality O3 211.0 124.7 PM10 159.8 132.4 SO2 99.5 58.3 CO 3.0 1.3 NO2 204.0 126.6 PM2.5 167.0 10.0 Overall 25.3 22.3 C) Respiratory mortality O3 209.3 159.2 PM10 43.2 32.8 SO2 35.1 19.6 NO2 291.7 153.0 PM2.5 490.0 168.0 Overall 76.9 67.4 D) Hospitalization O3 246.5 111.0 PM10 563.4 481.2 NO2 128.6 12.5 SO2 418.6 68.3 PM2.5 1558.0 630.5 Overall 60.9 323.7
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Table 4. Pooled numbers of all-cause mortality related to O3, PM2.5, PM10, NO2, NOx, SO2 and CO.
ACCEPTED MANUSCRIPT Table 5. The percent change of all-cause, cardiovascular and respiratory mortality (95% CI) for a 10-µg/m3 increase in the average concentration of PM10 and PM2.5 in this study compared with other studies cardiovascular mortality 0.9%, 95% CI 0.3%–1.4% 0.43%, 95% CI 0.37%–0.5% 0.9%, 95% CI 0.5%–1.3% 0.58, 95% CI 0.22%–0.93% 0.44, 95% CI 0.19%–0.68% 0.7%, 95% CI 0.4%–1% – 0.44%, 95% CI 0.33%–0.54% 0.58, 95% CI 0.22%–0.93% 0.44, 95% CI 0.19%–0.68% 0.5%, 95% CI 0.1%–2.0%
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(Atkinson et al., 2012) (Shang et al., 2013) (Anderson et al., 2004) (Wong et al., 2008)(4 cities) (Wong et al., 2008) (3 Chinese cities) This study Study (Franklin et al., 2007) (Shang et al., 2013) (Wong et al., 2008)(4 cities) (Wong et al., 2008) (3 Chinese cities) This study
PM10 all-cause mortality 0.3%, 95% CI 0.1%–0.4% 0.32, 95% CI 0.28%–0.35% 0.6%, 95% CI 0.4%–0.8% 0.55, 95% CI 0.26%–0.85% 0.37, 95% CI 0.21%–0.54% 0.7%, 95% CI 0.6%–0.8% PM2.5 1.21%, 95% CI 0.29%– 2.14% 0.38%,95% CI 0.31%– 0.45% 0.55, 95% CI 0.26%–0.85% 1.37, 95% CI 0.21%–1.54% 1.5%, 95% CI 1.3%–1.7%
respiratory mortality 0.4%, 95% CI 0.1%–0.6% 0.32, 95% CI 0.23%–0.40% 1.3%, 95% CI 0.5%–2.0% 0.62, 95% CI 0.22%–1.02% 0.60, 95% CI 0.16%–1.04% 1.0%, 95% CI 0.6%–1.3%
RI PT
Study
1.03% 95% CI 0.02%–2.04% 0.51% 95% CI 0.30%–0.73% 0.62, 95% CI 0.22%–1.02% 0.60, 95% CI 0.16%–1.04% 0.8%, 95% CI 0.4%–1%
Identification
ACCEPTED MANUSCRIPT Records identified through database searching (N =1675)
Additional records identified through other sources (N =29; from reference)
Records screened (N =1507)
Records excluded (N =1424)
Full-text articles excluded, with reasons: Not relevant studies to CVD or Respiratory and COPD, N = 30 Abstract only, N= 5 Small sample sizes, N= 8 Letter comments, correspondence, N = 2
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Full-text articles assessed for eligibility (N =83)
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Screening
Records after duplicates removed (N =197)
Included
Studies included in qualitative synthesis (N =38)
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Fig 1. PRISMA Flowchart for literature selection and Study identification (Moher et al., 2015)
ACCEPTED MANUSCRIPT
( ! Ardabil
East Azerbaijan
Golestan
( ! Gilan
! (
Kurdistan
Hamadan ( !
5
Kermanshah
PM10 (µg/m3) 20 - 60
( ! Markazi
! (
( ! Ilam
Lorestan
! (
! (
Tehran
( Isfahan!
Yazd
! (
( and Bakhtiari Chaharmahal!
Khosestan
! (
( Boyer-Ahmad ! Kohgiluyeh and
Mortality ( !
! (
40 - 70
71 - 360
! (
361 - 1109
! (
1110 - 2141
EP ( ! Bushehr
( ! South Khorasan
Kerman ( !
! (Fars
AC C
131 - 269
! (
( ! Semnan
( ! Qom
61 - 100
101 - 130
Razavi Khorasan
SC
( ! Qazvin
( ! Mazandaran
M AN U
( ! Zanjan
TE D
West Azerbaijan
( ! North Khorasan
( !
RI PT
! (
( !
( !
Hormozgan ( !
Sistan and Baluchestan
ACCEPTED MANUSCRIPT
A
80
M AN U
PM2.5 (µg/m3)
200
100
Lower 230
Between 231-645
EP
TE D
60
All-cause mortality
Higher 642
AC C
PM10 (µg/m3)
100
SC
300
RI PT
B
40
Lower 210
Between 211-770
All-cause mortality
Higher 770
ACCEPTED MANUSCRIPT
A
B 2
1
0
M AN U
0.5
SC
1.0
RI PT
% Change
% Change
1.5
-1
NO2
O3
SO2
PM10
CO
C
AC C
5
0
Pooled
PM2.5
PM10
SO2
O3
NO2
NO
NOx
D 2.5 2.0
% Change
EP
10
% Change
PM2.5
TE D
Pooled
1.5 1.0 0.5
-5
0.0 Pooled
CO
NOx
NO2
NO
SO2
PM10
O3
Pooled
SO2
NO
PM2.5
PM10
O3
NO2
ACCEPTED MANUSCRIPT Highlights The relationship between exposure to air pollution with mortality and hospitalizations by conducting a systematic review and meta-analysis The risk of bias assessed by the Office of Health Assessment and Translation (OHAT) Method for each study included
AC C
EP
TE D
M AN U
SC
RI PT
The percent change of all-cause, cardiovascular and respiratory mortality and hospitalization (95% CI) for a 10-µg/m3 increase in the PM10, PM2.5, O3 and CO (per each 10 mg/m3)